JP2023150319A - electronic stethoscope - Google Patents

Abstract

To provide an electronic stethoscope capable of acquiring a biological sound while the chest piece of an electronic stethoscope is in contact with an object of stethoscopy, with an appropriate pressure.SOLUTION: The electronic stethoscope comprises: a sound collecting part 10 for acquiring a biological sound with a microphone 1; and a supporting part 20 of the sound collecting part 10. The sound collecting part 10 includes a pressure sensor 7 for detecting a pressure in contact with the object of stethoscopy. The supporting part 20 includes an adhesive member 6 adhering to the object of stethoscopy and is configured to move the sound collecting part 10 in a direction of protruding toward the object of stethoscopy or in a direction opposite to it and support the sound collecting part 10 so as to be fixable at a position after the movement.SELECTED DRAWING: Figure 1

Description

The present invention relates to an electronic stethoscope, and more particularly to an electronic stethoscope that allows even a person who is not accustomed to using an electronic stethoscope to obtain body sounds when the chest piece and the object to be auscultated are in contact with each other with appropriate contact pressure. Regarding.

In telemedicine, patients (targeted for auscultation) and their family members who are not accustomed to using a stethoscope use an electronic stethoscope to obtain body sounds such as heart sounds, and the body sound signals that have undergone signal processing are transmitted to the patient. In some cases, the information is sent from an information communication terminal to a doctor's information communication terminal connected via the Internet, etc., and the patient receives an examination from the doctor.

However, when a person who is not accustomed to using an electronic stethoscope acquires body sounds, the vibrations of the hand holding the electronic stethoscope's chest piece and noises such as scraping sounds caused by the patient's movements can be detected. be mixed into the

As a method for auscultation without holding a stethoscope, a stethoscope in which a chest pad is fixed to a patient using a suction cup has been disclosed (Patent Document 1).

Utility model registration No. 3222551

Conventionally proposed stethoscopes can be fixed to the object of auscultation without holding the stethoscope, but the contact pressure between the diaphragm of the stethoscope and the body surface of the object of auscultation cannot be adjusted. Therefore, when the contact pressure is small, the signal level of the body sounds is low and the body sounds cannot be detected. On the other hand, if the contact pressure is too large, the body sound signal converted from the body sound will be distorted and noise will also increase. Therefore, there is a problem in that desired body sound signals cannot be obtained unless the contact pressure between the diaphragm of the stethoscope and the object to be auscultated is appropriate.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide an electronic stethoscope that can acquire body sounds while the chest piece of the electronic stethoscope and the object to be auscultated are in contact with each other with appropriate pressure.

The electronic stethoscope of the present invention is an electronic stethoscope that includes a sound collection section that acquires body sounds with a microphone, and a support section for the sound collection section, wherein the sound collection section comes into contact with an object to be auscultated. The support part includes a pressure sensor that detects pressure, and the support part includes an adhesive part that adheres to the auscultation target, and moves the sound collection part in a direction in which the sound collection part protrudes toward the auscultation target side or in the opposite direction. The sound collecting section is fixedly supported by the sound collecting section.

According to the electronic stethoscope of the present invention, the sound collecting portion of the chest piece and the auscultation target come into contact with each other with a pressure suitable for acquiring body sounds, and it is possible to acquire body sounds at an appropriate signal level.

FIG. 1 is an explanatory diagram of an electronic stethoscope that is an embodiment of the present invention, and is a diagram illustrating the structure of the electronic stethoscope. 1 is an explanatory diagram of an electronic stethoscope that is an embodiment of the present invention, and is a diagram illustrating signal processing of the electronic stethoscope. FIG. FIG. 6 is a diagram illustrating a body sound signal output when an electronic stethoscope is brought into contact with an auscultation target with varying contact pressure.

The electronic stethoscope of the present invention will be described with reference to the drawings, but the present invention is not limited to these embodiments, and the members, materials, etc. described below may be used within the scope of the spirit of the present invention. It can be modified in various ways. In addition, the same reference numerals in the drawings indicate the same or the same thing, and the sizes and positional relationships between each component are for convenience and do not reflect the actual situation.

(Embodiment)
FIG. 1 is an explanatory diagram of an embodiment of the electronic stethoscope of the present invention, in which (a) is a schematic cross-sectional view of the chest piece of the electronic stethoscope, and (b) is a contact surface of the chest piece that contacts a contact target. A schematic plan view is shown. FIG. 2 is an explanatory diagram of one embodiment of the electronic stethoscope of the present invention, and is a diagram illustrating signal processing of the electronic stethoscope.

A chest piece 100 of an electronic stethoscope according to the present embodiment shown in FIG. .

The sound collecting section 10 is provided with a sound collecting space 2 connected to the microphone 1. When the sound collection unit 10 comes into contact with the object to be auscultated, body sounds are transmitted to the sound collection space 2 through the membrane 3 covering the sound collection space 2, and the microphone 1 converts the body sounds into electrical signals. This electrical signal is processed by a signal processing device 5 located in the rear chamber 4 and output as a body sound signal to an earpiece (not shown), earphones, headphones, speakers, information communication terminals for remote medical treatment, etc. , a doctor makes a diagnosis, etc. Signal processing by the signal processing device 5 is performed by a body sound signal generation unit 51 in the signal processing device 5 shown in FIG. converted. The converted body sound signal is output to an output section 30 such as an earpiece. The body sound signal output from the signal processing device 5 to the output unit 30 can be transmitted by wire or wirelessly.

When the microphone 1 is configured with a capacitive MEMS transducer, the pressure inside the sound collection space 2 changes as the membrane 3 vibrates, and the MEMS transducer detects the capacitance change and performs signal processing to convert it into a biological sound signal. converted. The microphone 1 is not limited to a capacitive MEMS transducer, and a piezoelectric element, an electric condenser microphone, or the like can be used.

When a person who is not accustomed to handling an electronic stethoscope contacts the chest piece 100 with an object to be auscultated, the contact pressure may not be set to an appropriate pressure, or the contact pressure may not be kept constant during auscultation. There is. If the pressure with which the chest piece 100 is pressed against the object to be auscultated is not appropriate as described above, the desired body sound signal cannot be obtained, which is undesirable.

Therefore, in the electronic stethoscope according to the present embodiment, in order to enable even a person who is not accustomed to handling the chest piece 100 to contact the object to be auscultated with an appropriate contact pressure, the sound collecting section 10 is bonded to the object to be auscultated. , a support part 20 is provided for fixing the sound collecting part 10 by moving the position of the sound collecting part 10 in the direction of projecting the sound collecting part 10 toward the auscultation target side or in the opposite direction.

An adhesive member 6 such as an adhesive sticker is disposed on the support portion 20 as an adhesive portion on the surface that comes into contact with the auscultation target. In the example shown in FIG. 1B, an adhesive member 6 made of donut-shaped adhesive tape is placed on the contact surface with the auscultation target. The adhesive member 6 can also be an adhesive tape divided into a plurality of pieces. Further, instead of the adhesive tape, for example, a structure may be adopted that includes a general suction cup, or a structure may be adopted in which a space is formed inside the support part 20 and the space is made to have a negative pressure to function as a suction cup. By appropriately selecting the adhesive portion, the support portion 20 can be adhered to the object to be auscultated with a certain adhesive force depending on the type of the adhesive portion without touching the chest piece 100 of the electronic stethoscope.

The support section 20 supports the sound collection section 10 so that it can be moved in a direction in which the sound collection section 10 projects toward the auscultation target side or in the opposite direction, and fixed at the moved position. By moving the position of the sound collecting section 10, the contact pressure between the sound collecting section 10 and the object to be auscultated can be adjusted.

As an example, a threaded portion 8A is formed in the sound collecting portion 10 shown in FIG. 1(a), and a threaded hole 8B is formed in the support portion 20 so as to engage with this threaded portion 8A. The sound collecting section 10 is supported by the support section 20 by the engaging section 8 constituted by the screw section 8A and the screw hole 8B.

As shown in FIG. 1(b), when the contact surface of the sound collecting section 10 with the auscultation object is circular and the rotary disk 9 connected to the sound collecting section 10 is rotated, the threaded section 8A rotates, and the direction of rotation is Depending on the situation, the sound collecting section 10 can be moved in the direction of protruding toward the auscultation object side, or in the opposite direction, in the direction of moving away from the auscultation object and into the inside of the sound collecting section 10. As a result, the contact pressure between the sound collecting section 10 and the auscultation target changes. When the rotation of the rotary disk 9 is stopped, the sound collecting section 10 can be fixed at that position.

Further, in the electronic stethoscope according to the present embodiment, a pressure sensor 7 is arranged on the surface of the sound collecting section 10 that comes into contact with the object to be auscultated. In the example shown in FIG. 1(b), four pressure sensors 7 are arranged. These pressure sensors 7 detect the contact pressure of the contact surface between the sound collecting section 10 and the auscultation object when the support section 20 of the chest piece 100 is adhered to the auscultation object by the adhesive member 6 . When the surface of the sound collection unit 10 contacts the auscultation target with an appropriate contact pressure, the sound collection unit 10 can acquire body sounds at an appropriate signal level.

If the pressure value detected by the pressure sensor 7 is not an appropriate contact pressure, the position of the sound collecting section 10 is moved to adjust the contact pressure between the sound collecting section 10 and the auscultation object to an appropriate pressure value.

Whether the pressure value detected by the pressure sensor 7 is an appropriate contact pressure is determined as follows. For example, as shown in FIG. 2, the signal processing device 5 includes a comparison section 52 into which the pressure value output from the pressure sensor 7 is input, and a memory that stores in advance a set pressure range that provides an appropriate contact pressure and outputs it to the comparison section 52. The configuration includes a section 53. As the pressure sensor 7, for example, a pressure-sensitive resistance element that changes the resistance value between two electrodes when pressure is sensed can be used.

The set pressure range stored in the storage unit 53 is set from the body sound signal obtained by bringing the sound collecting unit 10 into contact with the auscultation target while changing the contact pressure with the chest piece 100 adhered to the auscultation target. For example, FIG. 3 shows a body sound signal obtained when the sound collection unit 10 is brought into contact with an auscultation target with different contact pressures. In FIG. 3, (a) shows the body sound signal when the contact pressure between the sound collection unit 10 and the auscultation target is low, and (b) shows the body sound signal when the contact pressure is higher than that shown in (a). (c) shows the body sound signals when the contact pressure is higher than that shown in (b). Comparing (a) to (c) in Fig. 3, it is found that when the contact pressure shown in (a) is used, no biological sound signal can be obtained, and when the contact pressure is set as shown in (c), no biological sound signal is obtained. Some signals are largely saturated. On the other hand, it can be seen that when the contact pressure shown in (b) is used, a biological sound signal with less noise can be obtained. By confirming in advance the contact pressure at which a body sound signal with less noise is obtained, the contact pressure range at which a desired body sound signal is obtained is determined.

As shown in FIG. 2, the contact pressure range confirmed in advance is stored in the storage unit 53 as a set pressure range. The pressure value output from the pressure sensor 7 and the set pressure range stored in the storage unit 53 are input to the comparison unit 52, and it is checked whether the pressure value output from the pressure sensor 7 is within the set pressure range. It will be judged. The determination result is output to the notification section 40. The notification unit 40 makes the subject of auscultation, the person handling the electronic stethoscope, or the doctor conducting remote medical treatment aware of the determination result. It changes the state. It is also possible to adopt a configuration in which a sound is emitted from a speaker, or a configuration in which a determination result is displayed in text on a display device. Note that the notification unit 40 such as an LED, a speaker, a display device, etc. does not necessarily need to be integrated with the electronic stethoscope, especially the chest piece, and may only have a configuration that transmits the determination result to the notification unit 40. may be included in the electronic stethoscope.

If the determination result is that the contact pressure of the sound collection unit 10 is within the set pressure range, the body sound signal output in that state is the body sound signal obtained by acquiring body sounds at an appropriate signal level. Become. On the other hand, if the determination result is that the contact pressure of the sound collecting section 10 is outside the set pressure range, move the position of the sound collecting section 10 and compare the contact pressure of the sound collecting section 10 with the set pressure range again. Obtain the judgment result. By repeating this, the contact pressure of the sound collecting section 10 can be kept within the set pressure range.

At the sound collection unit 10 where the pressure value has become suitable, the body sound acquired by the microphone 1 becomes a body sound at an appropriate signal level, and is converted into a body sound signal with less distortion and noise.

Even if a person is not accustomed to handling an electronic stethoscope, if the electronic stethoscope can be attached to the object to be auscultated and the contact pressure of the sound collecting section 10 can be adjusted, it is possible to obtain an appropriate signal level without noise. It becomes possible to acquire body sound signals.

Although one embodiment of the electronic stethoscope of the present invention has been described above, the present invention is not limited to the above embodiment and can be modified in various ways. For example, the output of the comparison unit 52 that determines whether the pressure value output from the pressure sensor 7 is within a set pressure range is input to the biological sound signal generation unit 51, and the pressure value output from the pressure sensor 7 is It is also possible to adopt a configuration in which the biological sound signal is output from the biological signal generation section 51 to the output section 30 only when the pressure is within the set pressure range. The method of changing the position of the sound collecting section 10 is not limited to the method of rotating a screw, and can be changed in various ways. For example, when the sound collection section 10 is pushed toward the auscultation object side, it is fixed at a position moved toward the auscultation object side by a predetermined distance, and the position of the sound collection section 10 may be changed depending on the number of times the sound collection section 10 is pushed. In this case, in order to move the pushed-in sound collecting section 10 in the opposite direction, that is, in the direction opposite to the side to be auscultated, the fixed state of the pushed in sound collecting section 10 is released, and the sound collecting section 10 is moved in the direction opposite to the side to be auscultated. It may be possible to move in the direction. Furthermore, the present invention is not limited to membrane-type chestpieces, but can also be applied to bell-shaped chestpieces.

(summary)
(1) An embodiment of the electronic stethoscope of the present invention is an electronic stethoscope including a sound collecting section for acquiring body sounds with a microphone, and a support section for the sound collecting section, the electronic stethoscope including: is provided with a pressure sensor that detects the pressure in contact with the auscultation target, and the support part includes an adhesive part that adheres to the auscultation target, and the sound collecting part is protruded toward the auscultation target or in the opposite direction. The sound collecting section may be moved to a position where the sound collecting section is moved, and the sound collecting section may be fixedly supported at the moved position.

According to the electronic stethoscope of the present embodiment, the sound collection unit and the auscultation target come into contact with each other with suitable pressure for acquiring body sounds, and it is possible to acquire body sounds at an appropriate signal level.

(2) The sound collecting section includes a threaded part that connects with the supporting part, and the supporting part has a screw hole that engages with the threaded part, and the sound collecting part is moved by rotation of the threaded part. The sound collecting section may be fixedly supported at a position where the rotation of the screw section is stopped.

(3) A memory unit that stores a preset pressure range, and compares the pressure detected by the pressure sensor with the pressure range stored in the memory unit, and the pressure detected by the pressure sensor is determined to be the pressure It may also be configured to include a comparison section that determines whether or not the range is within the range, and a notification section that notifies the determination result of the comparison section.

As a result, there is no need to perform auscultation while searching for the appropriate contact pressure between the sound collection part and the object to be auscultated each time. Even a person who is not accustomed to handling can easily obtain body sound signals without noise and at an appropriate signal level.

1 Microphone 2 Sound collection space 3 Membrane 4 Back chamber 5 Signal processing device 51 Body sound signal generation section 52 Comparison section 53 Storage section 6 Adhesive member 7 Pressure sensor 8 Engagement section 8A Screw section 8B Screw hole 9 Turntable 10 Sound collection section 20 Support part 30 Output part 40 Notification part 100 Chest piece

Claims (3)

a sound collection unit that acquires body sounds with a microphone;
An electronic stethoscope comprising: a support part for the sound collection part,
The sound collection unit includes a pressure sensor that detects pressure in contact with the auscultation target,
The support part includes an adhesive part that adheres to the auscultation target, and is capable of moving the sound collection part in a direction in which the sound collection part protrudes toward the auscultation target side or in the opposite direction, and fixing the sound collection part at the moved position. Supporting electronic stethoscope. The sound collecting section includes a threaded section that connects to the supporting section,
The supporting portion includes a screw hole that engages with the threaded portion, and is capable of moving the sound collecting portion by rotation of the threaded portion and fixing the sound collecting portion at a position where rotation of the threaded portion is stopped. To support,
The electronic stethoscope according to claim 1. a memory unit that stores a preset pressure range;
a comparison unit that compares the pressure detected by the pressure sensor with the pressure range stored in the storage unit and determines whether the pressure detected by the pressure sensor is within the pressure range;
The electronic stethoscope according to claim 1 or 2, further comprising a notification section that notifies the determination result of the comparison section.

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